# “painting” one array onto another using python / numpy

I'm writing a library to process gaze tracking in Python, and I'm rather new to the whole numpy / scipy world. Essentially, I'm looking to take an array of (x,y) values in time and "paint" some shape onto a canvas at those coordinates. For example, the shape might be a blurred circle.

The operation I have in mind is more or less identical to using the paintbrush tool in Photoshop.

I've got an interative algorithm that trims my "paintbrush" to be within the bounds of my image and adds each point to an accumulator image, but it's slow(!), and it seems like there's probably a fundamentally easier way to do this.

Any pointers as to where to start looking?

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Sounds like you want some form of quick blit. However I lack knowledge of python to suggest a good answer. –  Sekhat Jan 18 '10 at 11:41

In your question you describe a Gaussian filter, for which scipy has support via a package. For example:

``````from scipy import * # rand
from pylab import * # figure, imshow
from scipy.ndimage import gaussian_filter

# random "image"
I = rand(100, 100)
figure(1)
imshow(I)

# gaussian filter
J = gaussian_filter(I, sigma=10)
figure(2)
imshow(J)
``````

Of course, you can apply this on the whole image, or just on a patch, using slicing:

``````J = array(I) # copy image
J[30:70, 30:70] = gaussian_filter(I[30:70, 30:70], sigma=1) # apply filter to subregion
figure(2)
imshow(2)
``````

For basic image manipulation, the Python Image library (PIL) is probably what you want.

NOTE: for "painting" with a "brush", I think you could just create a boolean mask array with your brush. For instance:

``````# 7x7 boolean mask with the "brush" (example: a _crude_ circle)
mask = array([[0, 0, 1, 1, 1, 0, 0],
[0, 1, 1, 1, 1, 1, 0],
[1, 1, 1, 1, 1, 1, 1],
[1, 1, 1, 1, 1, 1, 1],
[1, 1, 1, 1, 1, 1, 1],
[0, 1, 1, 1, 1, 1, 0],
[0, 0, 1, 1, 1, 0, 0]], dtype=bool)

# random image
I = rand(100, 100)
# apply filter only on mask
# compute the gauss. filter only on the 7x7 subregion, not the whole image
``````
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Hm, this may put me on the right track -- I think some slicing magic will help me do what I need. –  Nate Dec 22 '09 at 22:00
I added an example with a boolean mask, maybe that's what you need. –  catchmeifyoutry Dec 22 '09 at 22:09
this is nice +1 :) –  Nope Dec 22 '09 at 23:33

OpenCV uses numpy arrays and has basic drawing functions: circles, elipses, polylines...

To draw a line you can call

``````cv.line(array,previous_point,new_point,colour,thickness=x)
``````

each time you get a mouse event.

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Doing a little of math in Fourier space may help: a translation (convolution by a dirac) is equal to a simple multiplication by a phase in Fourier... this makes your paintbrush move to the exact place (a similar solution than catchmeifyoutry & dwf, but this allows a translation finer than the pixel, like 2.5, alas with some ringing). Then, a sum of such strokes is the sum of these operations.

In code:

``````import numpy
import pylab
from scipy import mgrid

def FTfilter(image, FTfilter):
from scipy.fftpack import fftn, fftshift, ifftn, ifftshift
from scipy import real
FTimage = fftshift(fftn(image)) * FTfilter
return real(ifftn(ifftshift(FTimage)))

def translate(image, vec):
"""
Translate image by vec (in pixels)

"""
u = ((vec[0]+image.shape[0]/2) % image.shape[0]) - image.shape[0]/2
v = ((vec[1]+image.shape[1]/2) % image.shape[1]) - image.shape[1]/2
f_x, f_y = mgrid[-1:1:1j*image.shape[0], -1:1:1j*image.shape[1]]
trans = numpy.exp(-1j*numpy.pi*(u*f_x + v*f_y))
return FTfilter(image, trans)

# combine in oclusive mode

if __name__ == '__main__':
Image = numpy.random.rand(100, 100)
X, Y = mgrid[-1:1:1j*Image.shape[0], -1:1:1j*Image.shape[1]]
brush = X**2 + Y**2 < .05 # relative size of the brush
# shows the brush
pylab.imshow(brush)

# move it to some other position  / use a threshold to avoid ringing
brushed = translate(brush, [20, -10.51]) > .6
pylab.imshow(brushed)

pylab.imshow(occlude(Image, brushed))

more_strokes = [[40, -15.1], [-40, -15.1], [-25, 15.1], [20, 10], [0, -10], [25, -10.51]]
for stroke in more_strokes:
brushed = brushed + translate(brush, stroke) > .6

pylab.imshow(occlude(Image, brushed))
``````
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You should really look into Andrew Straw's motmot and libcamiface. He uses it for fly behaviour experiments but it's a flexible library for doing just the kind of image acquisition and processing you're doing I think. There's a video of his presentation at SciPy2009.

As for the paintbrush scenario you mention, I'd make a copy of the image with the .copy() method, keep the paintbrush image in an array, and simply add it with

``````arr[first_br_row:last_br_row, first_br_col:last_br_col] += brush[first_row:last_row, first_col:last_col]
``````

where you set `first_br_row`, `last_br_row` `first_br_col`, `last_br_col` to address the subimage where you want to add the brush and `first_row`, `last_row`, `first_col`, `last_col` to clip the brush (normally set them to 0 and # rows/cols - 1, but adjust when you're near enough to the image boundary to only want to paint part of the brush).

Hope all that helps.

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Thanks! Turns out that yes, slicing and indexing tricks will help a bunch. However! The Right Answer is probably to draw individual points and apply the brush and blur both as kernels. Thanks for the bump on the libraries; however, this is really a post-processing task: the data have already been collected. –  Nate Jan 7 '10 at 18:49